Transactional controls for supplying control plane data to managed hardware forwarding elements

ABSTRACT

Some embodiments provide novel methods for controllers to communicate with managed hardware forwarding elements (MHFEs) in a transactional manner. The transactional communication methods of some embodiments ensure that an MHFE receives the entirety of a control plane update that a controller supplies to it, before the MHFE starts to modify its data plane forwarding data and operations. The transactional communication methods of some embodiments provide one or more transactional boundary controls to the controllers to define complete control plane data set updates. In some embodiments, the transactional controls ensure that an MHFE receives all of a control plane update before it starts to modify its data plane forwarding data. Controllers use one transactional control in some embodiments when they define logical forwarding elements (e.g., logical switches or routers) on the MHFEs.

BACKGROUND

Today, several network control systems configure software forwardingelements executing on host computers to create logical forwardingelements that span multiple host computers. Such logical forwardingelements allow multiple isolated logical networks to be created on ashared physical network infrastructure. In recent years, some networkcontrol systems have been adapted to configure hardware forwardingelements, such as top of the rack (TOR) switches. In many such cases,the TORs have configuration databases that are defined according to thehardware VTEP (VXLAN Tunnel Endpoint) schema. Network controllers ofsuch network control systems communicate with such TOR configurationdatabases using the OVSdb protocol. The OVSdb protocol and hardware VTEPschema are defined by the Open vSwitch organization.

The hardware VTEP schema defines various tables to exchange controlplane information between a controller and a TOR. However, neither thisschema nor the OVSdb protocol require the controllers to usetransactional controls in communicating with the TORs. As such, onreceiving a portion of a configuration from a controller, the TOR mightstart modifying its data plane operation. This may cause problems as thereceived configuration data portion might provide a view of the logicalnetwork that is incomplete and in some cases, inconsistent with eitheran earlier logical network view upon which the TOR previously based itsdata plane operation, or with the current logical network view that thecontroller is trying to push to the TOR. Therefore, there is a need inthe art for transactional controls for the network controllers to use toallow TORs to update their data plane operations based on completecontrol plane views of the logical networks.

BRIEF SUMMARY

Some embodiments provide novel methods for controllers to communicatewith managed hardware forwarding elements (MHFEs) in a transactionalmanner. The transactional communication methods of some embodimentsensure that an MHFE receives the entirety of a control plane update thata controller supplies to it, before the MHFE starts to modify its dataplane forwarding data and operations.

The network controllers in some embodiments manage the MHFEs to createone or more logical networks that span shared physical forwardingelements, including the MHFEs. In some embodiments, the shared physicalforwarding elements also include software forwarding elements executingon host computers, on which multiple compute nodes (e.g., virtualmachines, containers, etc.) execute. The transactional communicationmethods of some embodiments ensure that the MHFEs update their dataplane operations based on complete control plane views of logicalnetworks.

The transactional communication methods of some embodiments provide oneor more transactional boundary controls to the controllers to definecomplete control plane data set updates. In some embodiments, thetransactional controls ensure that an MHFE receives all of a controlplane update before it starts to modify its data plane forwarding data.Controllers use one transactional control in some embodiments when theydefine logical forwarding elements (e.g., logical switches or routers)for the first time on the MHFEs.

In some embodiments, one configuration data tuple that is needed tocreate a logical forwarding element on an MHFE is a data tuple thatbinds (i.e., associates) the logical forwarding element with a physicalport of the MHFE (e.g., a port of a hardware top-of-rack switch). Thisconfiguration data tuple is referred to below as the LAN (local areanetwork) binding tuple. In pushing configuration data to an MHFE todefine a logical forwarding element (LFE) on the MHFE, the controller insome embodiments supplies other configuration data tuples to the MHFEbefore the LAN binding tuple. In some of these embodiments, thecontroller supplies the LAN binding tuple as the last configuration datatuple to the MHFE. This is because the MHFE in some embodiments startsto create its data plane forwarding records for the LFE once the MHFEreceives the LAN binding tuple.

In some embodiments, the MHFEs use the hardware-VTEP schema. In thisschema, there is a Logical_Switch table where the controller createslogical switches, and a Ucast_Macs_Remote table, where the controllerprovides the forwarding information for those logical switches. Anothertable in this schema is the Physical_Port table, which includes avlan_bindings column that binds specific VLANs on the specific physicalports of the hardware VTEP device (i.e., of an MHFE) to correspondinglogical switches. To achieve transactional semantics for a logicalswitch, the controllers of some embodiments propagate all modificationsto the Logical_Switch table and the Ucast_Macs_Remote table beforeupdating the vlan_bindings column in the Physical_Port table for a newlogical switch that the controller is defining on the MHFE.

When updating a logical network's control plane data, some embodiments(1) delete the vlan_binding tuple in the Physical_Port table to unbindthe logical switch from the physical network, (2) update theconfiguration data in one or more MHFE's tables (e.g., forwardinginformation in Ucast_Macs_Remote table), and then (3) recreate thebinding in the vlan_bindings column. This approach requires the logicalswitch to stop forwarding during the time between when the vlan_bindingtuple is deleted and when it is added back. In other words, during thistime, there will be a data plane outage.

Accordingly, other embodiments use other transaction controls to updatethe control plane configuration data of a logical switch that is alreadydefined on an MHFE, instead of unbinding the logical switch from theMHFE. In some embodiments, an MHFE creates a lock for a logicalforwarding element that is defined on it. In some of these embodiments,the controller can “steal” this lock (e.g., can take this lock even whenanother MHFE module is using it to access the hardware VTEP database)during a period in which the controller updates the configuration dataof a logical forwarding element (LFE). While the controller has stolenthe LFE's lock, no MHFE module examines its configuration data storageto detect changes to the configuration data and to update its data planeforwarding records based on such detected changes. Once the controllercompletes its control plane configuration update for a LFE implementedby the MHFE, the controller returns the lock for the LFE (i.e.,relinquishes the lock), at which point an MHFE module can request thelock for the LFE, can detect changes to the LFE's control planeconfiguration, and then can update its data plane forwarding data basedon these detected changes.

In the embodiments where the MHFE uses the hardware VTEP schema, thisschema supports creation of a “lock” for one or more records in thehardware VTEP database. Once a lock is created for a record, a hardwareVTEP database client can use the following commands to communicate witha hardware VTEP database server (for the hardware VTEP database)vis-à-vis the lock: lock request, lock steal request, and lock release.Lock request is a request to obtain the lock for a data record in orderto read and/or write to the data record. When another database clienthas a lock for the data record, a lock request does not cause thedatabase server to remove the lock from the other database client toprovide the lock to the database client that requested the lock. A locksteal request, however, does cause the database server to remove thelock from another database client that currently has the lock in orderto provide the lock to the database client that provided the lock stealrequest. When a database client is done with a lock, it provides a lockrelease command to the database server to release the lock.

Some embodiments create a lock for a logical switch record in theLogical_Switch table. Once a binding in the vlan_bindings column isestablished, a database client on the MHFE acquires a lock for thelogical switch by providing the logical switch's identifier along withthe lock request to the MHFE's hardware VTEP database server.Subsequently, when the controller wishes to change the logical switch'sconfiguration (e.g., the logical switch's control plane data records),the controller's hardware VTEP database client provides a lock stealrequest and the logical switch's identifier to the database server.

The MHFE's database server provides a notification to its databaseclient that the lock has been stolen, which indicates a forthcomingchange to the forwarding information. The MHFE's database client triesto re-acquire the lock. However, its attempts fail as long as thecontroller is holding the stolen lock while it makes changes. Theforwarding plane continues to work according to the forwardinginformation of the last transaction, i.e., there is no outage. After thecontroller is done with making its changes, it releases the lock for thelogical switch. At this point, the MHFE's database client's lockre-acquisition operation succeeds. When the MHFE database client is ableto re-acquire the lock, it applies all the changes that the controllermade to the forwarding table to its forwarding plane. Thus, in thismanner, the forwarding plane for the logical switch is transactionallyupdated in some embodiments.

Instead of using the lock-based approach, other embodiments define aconfiguration data tuple that the controller uses to explicitly informthe MHFE that the control plane configuration data is being updated andhence might not provide a consistent view of a logical forwardingelement or a logical network. For instance, instead of using thelock-based approach, some embodiments change the hardware VTEP schema toadd a Boolean column to the Logical_Switch table to indicate whether thelogical switch's information in the hardware VTEP database is consistentfrom the controller's point of view. This column is referred to below asthe state_consistent column.

In some embodiments, the controller initializes this column to Falsewhile creating a logical switch. The controller is free to update thevlan_binding column at any point for this logical switch. Aftersupplying all the data tuples for the logical switch (e.g., all the datatuples to the Ucast_Macs_Remote table, Mcast_Macs_Remote table, andPhysical_Port table), the controller updates the state_consistent columnto True. Once that happens, the MHFE database client modifies the MHFE'sforwarding tables in the data plane based on the supplied logical switchconfiguration tuples.

When the controller wants to modify the MHFE's control planeconfiguration for a logical switch, the controller first changes thestate_consistent column to False. The MHFE agent monitors this column.When the column becomes False, the MHFE's forwarding records in the dataplane continue to work in its last transactional state. The controllermakes the changes to the MHFE's hardware VTEP database, and then changesthe state_consistent column to True. At this point, the MHFE's databaseclient applies all changes to its forwarding records in the data planes.

The preceding Summary is intended to serve as a brief introduction tosome embodiments of the invention. It is not meant to be an introductionor overview of all inventive subject matter disclosed in this document.The Detailed Description that follows and the Drawings that are referredto in the Detailed Description will further describe the embodimentsdescribed in the Summary as well as other embodiments. Accordingly, tounderstand all the embodiments described by this document, a full reviewof the Summary, Detailed Description, the Drawings and the Claims isneeded. Moreover, the claimed subject matters are not to be limited bythe illustrative details in the Summary, Detailed Description and theDrawing.

BRIEF DESCRIPTION OF THE DRAWINGS

The novel features of the invention are set forth in the appendedclaims. However, for purposes of explanation, several embodiments of theinvention are set forth in the following figures.

FIG. 1 illustrates four of tables that are defined in the OVSdb schema.

FIG. 2 illustrates a modified Logical Switch table with astate_consistent column.

FIG. 3 conceptually illustrates a network control system that implementsthe MHFE management methods of some embodiments of the invention.

FIG. 4 conceptually illustrates how a network controller communicateswith a software switch and a hardware switch in some embodiments.

FIG. 5 conceptually illustrates a process that a physical controllerperforms in some embodiments to supply the definition of a logicalforwarding element to an MHFE in a transactional manner.

FIG. 6 conceptually illustrates a process that a TOR's OVSdb serverperforms to define a logical switch on the TOR.

FIG. 7 conceptually illustrate the processes that the TOR agent, OVSdbserver and the OVSdb client perform in some embodiments during and aftera period in which the TOR agent modifies the records of a logical switchin the OVS database.

FIG. 8 conceptually illustrates a process that a TOR agent performs insome embodiments to supply define a logical switch or modify a logicalswitch definition in a transactional manner for a TOR.

FIG. 9 conceptually illustrates a process that a hardware switch's OVSdbserver performs to create a logical switch on the hardware switch, or toupdate the configuration of a previously created logical switch on thehardware switch.

FIG. 10 conceptually illustrates a computer system that implementsprocesses of some embodiments of the invention.

DETAILED DESCRIPTION

In the following detailed description of the invention, numerousdetails, examples, and embodiments of the invention are set forth anddescribed. However, it will be clear and apparent to one skilled in theart that the invention is not limited to the embodiments set forth andthat the invention may be practiced without some of the specific detailsand examples discussed.

Some embodiments provide novel methods for controllers to communicatewith managed hardware forwarding elements (MHFEs) in a transactionalmanner. The transactional communication methods of some embodimentsensure that an MHFE receives the entirety of a control plane update thata controller supplies to it, before the MHFE starts to modify its dataplane forwarding data and operations. Examples of MHFEs includetop-of-rack (TOR) switches.

The network controllers in some embodiments manage the MHFEs to createone or more logical forwarding elements that span shared physicalforwarding elements, including the MHFEs. In some embodiments, theshared physical forwarding elements also include software forwardingelements executing on host computers, on which multiple data computenodes (DCNs, such as virtual machines, containers, etc.) execute. Thelogical forwarding elements allow multiple logical networks to becreated on a shared physical compute and network infrastructure.

Each logical network's set of one or more logical forwarding elements(LFEs) can connect DCNs (e.g., virtual machines, containers, etc.) thatexecute on different host computers. Each LFE is an abstract constructthat conceptually spans multiple forwarding elements (e.g., softwareforwarding elements, SFEs) to connect DCNs on multiple different hoststo each other. In some embodiments, overlay tunnel connections betweenthe hosts facilitate the creation of the LFEs. Each logical network canisolate the traffic exchanged between its DCNs from the traffic fromDCNs of other logical networks. Many examples of logical networks andlogical forwarding elements are described in U.S. Published PatentApplication 2013/0058335, U.S. Pat. No. 8,958,298, U.S. Published PatentApplication 2015/0063360, and U.S. Published Patent Application2015/0263946.

As used in this document, data messages or packets generically refer toa collection of bits in a particular format sent across a network. Oneof ordinary skill in the art will recognize that the term data messageor packet may be used herein to refer to various formatted collectionsof bits that may be sent across a network, such as Ethernet frames, IPpackets, TCP segments, UDP datagrams, etc. Also, as used in thisdocument, references to L2, L3, L4, and L7 layers (or layer 2, layer 3,layer 4, layer 7) are references respectively to the second data linklayer, the third network layer, the fourth transport layer, and theseventh application layer of the OSI (Open System Interconnection) layermodel.

The transactional communication methods of some embodiments ensure thatthe MHFEs update their data plane operations based on complete controlplane views of logical networks. The transactional communication methodsof some embodiments provide one or more transactional boundary controlsto the controllers to define complete control plane data set updates. Insome embodiments, the transactional controls ensure that an MHFEreceives all of a control plane update before it starts to modify itsdata plane forwarding data.

Controllers use one transactional control in some embodiments when theydefine logical forwarding elements (e.g., logical switches or routers)for the first time on the MHFEs. In some embodiments, one configurationdata tuple that is needed to create a logical forwarding element on anMHFE is a data tuple that binds (i.e., associates) the logicalforwarding element with a physical port of the MHFE (e.g., a port of aTOR switch). This configuration data tuple is referred to below as theLAN (local area network) binding tuple. In pushing configuration data toan MHFE to define a logical forwarding element (LFE) on the MHFE, thecontroller in some embodiments supplies other configuration data tuplesto the MHFE before the LAN binding tuple. In some of these embodiments,the controller supplies the LAN binding tuple as the last configurationdata tuple to the MHFE. This is because the MHFE in some embodimentsstarts to create its data plane forwarding records for the LFE once theMHFE receives the LAN binding tuple.

The MHFEs in some embodiments contain configuration databases andexecute database servers with which the network controllers can interactthrough a database protocol. For instance, in some embodiments, the WIFEconfiguration database is a hardware VTEP database and the communicationprotocol is an OVSdb (an Open Virtual Switch (OVS) database) protocol.In some embodiments, the hardware VTEP schema for the MHFE specifiesmultiple WIFE database tables to which a controller can write. In thehardware VTEP schema, the LAN binding tuple is defined in one column ofthe Physical_Port table of this schema.

FIG. 1 illustrates this table along with three other tables in thehardware VTEP schema. The illustrated tables are the Ucast_Macs_Remotetable 105, Mcast_Macs_Remote table 110, the Logical_Switch table 115,and the Physical_Port table 120. In an MHFE's database, theLogical_Switch table 115 contains a record for each logical switchimplemented by the MHFE. For each logical switch that the MHFEimplements, a controller in some embodiments creates a record in theLogical_Switch table 115. As shown, each logical switch's recordincludes (1) a UUID (universally unique identifier) 122 tuple thatprovides a universal unique identifier for the logical switch, (2) adescription 124 that provides a textual description of the logicalswitch, (3) a name tuple 126 that provides the name of the logicalswitch, and (4) a tunnel_key 128 that provides the VNI (VXLAN networkidentifier) of the logical switch.

The Ucast_Macs_Remote table 105 provides the forwarding information forthe logical switches. The Ucast table provides the unicast MAC (mediaaccess control) addresses for the DCNs (VMs, containers, etc.)associated with each logical switch. Optionally, this table alsoprovides the IP (Internet Protocol) address of each of these VMs. Thistable also provides the VTEP IPs for each logical switch.

As shown, each record in the Ucast_Macs_Remote table 105 includes (1) alogical switch field 132 that specifies the logical switch with which aport of an end machine is associated (in the case that the table isinstantiated on an L3 MHFE, this field also specifies the logical routerports associated with the logical switch), (2) a MAC address field 134that specifies the corresponding MAC address of the port (the MACaddress of the end machine's port associated with the logical switch'sport), (3) an optional field 136 that can include an IP addressassociated with the MAC address, and (4) a locator field 138 thatspecifies the IP address of the VTEP for the corresponding MAC address.

Because of the locator field 138, the Ucast table 105 is referred to asa tunnel endpoint locator table or a tunnel endpoint table. For an L2MHFE, the controllers in some embodiments supply the Ucast table withthe physical locator addresses (i.e., IP addresses) of the MFEs(hardware and software) that implement (1) the different logicalswitches' ports that are associated with the end machines of the logicalnetwork, and (2) the logical router ports that receive the L3 packetsfrom the MHFE. The Ucast table 105 specifies the next destination of aunicast packet with a unique destination MAC address. By locating theendpoints, the L2 MHFE is able to establish tunnels between the MHFE andother MFEs and exchange the network data through the establishedtunnels.

The Mcast_Macs_Remote table 110 is another tunnel endpoint locatortable. The Mcast table 110 specifies the next destination of abroadcast, multicast, or unknown unicast packet that does not have aunique destination MAC address. As shown, the table 110 has threedifferent fields 142, 144, and 146 that are similar to the fields 132,134, and 138 of Ucast table 105, with the exception that Mcast table 110is for the destination MAC addresses that are not known to the MHFE orthe destination MAC addresses of multicast and broadcast packets in someembodiments. The controllers in some embodiments configure the locatorcolumn 146 of the Mcast tables 110 with IP addresses of service nodesthat process BUM (broadcast, unknown, and multicast) packets. This way,the MHFEs forward any BUM packet to service nodes for processing.

The Physical_Port table 120 is a table that is specified by the MHFEsand read by the controllers, except that the controller updates theVLAN_bindings column 158 to bridge VLANs (virtual LANs) on specificphysical ports of the MHFE to logical switches. As shown, this table 120includes three columns 152, 154 and 156 that define the port UUID, theport description, and the port name. The vlan_bindings column 158 is amap of a VLAN to a logical switch UUID. This column 158 establishes thelogical switch to physical port association (for given VLANs).

Updating the VLAN binding column is the transaction that causes alogical switch to bridge to the physical network. Some embodimentscontrol this update in order to provide a transactional boundary in thepushed transaction data. Specifically, to achieve transactionalsemantics for a logical switch, the controllers of some embodimentspropagate all configuration data to the MHFE (e.g., all the data to theLogical_Switch table 115, the Ucast_Macs_Remote table 105, and theMcast_Macs_Remote table 110) before updating the vlan_bindings column158 in the Physical_Port table 120.

When updating a logical network's control plane data, some embodiments(1) delete the vlan_binding tuple in the Physical_Port table 120 tounbind the logical switch from the physical network, (2) update theconfiguration data in one or more MHFE's tables (e.g., forwardinginformation in Ucast_Macs_Remote table 105), and then (3) recreate thebinding in the vlan_bindings column. This approach requires the logicalswitch to stop forwarding during the time between when the vlan_bindingtuple is deleted and when it is added back. In other words, during thistime, there will be a data plane outage.

Accordingly, other embodiments use other transaction controls to updatethe control plane configuration data of a logical switch that is alreadydefined on an MHFE, instead of unbinding the logical switch from theMHFE. In some embodiments, an MHFE creates a lock for a logicalforwarding element that is defined on it. In some of these embodiments,the controller can “steal” this lock (e.g., can take this lock even whenanother MHFE module is using it to access the hardware VTEP database)during a period in which the controller updates the configuration dataof a logical forwarding element (LFE). While the controller has stolenthe LFE's lock, no MHFE module examines its configuration data storageto detect changes to the configuration data and to update its data planeforwarding records based on such detected changes. Once the controllercompletes its control plane configuration update for a LFE implementedby the MHFE, the controller returns the lock for the LFE (i.e.,relinquishes the lock), at which point an MHFE module can request thelock for the LFE, can detect changes to the LFE's control planeconfiguration, and then can update its data plane forwarding data basedon these detected changes.

In the embodiments where the MHFE uses the hardware VTEP schema, thisschema supports creation of a “lock” for one or more records in thehardware VTEP database. Once a binding in the vlan_bindings column isestablished, a database server executing on the MHFE creates a lock forthe logical switch in some embodiments. The database server creates thislock at the direction of a database client on the controller in someembodiments. In some embodiments, this lock has an identifier thatidentifies the logical switch.

Once a lock is created for a record, a hardware VTEP database client canuse the following commands to communicate with a hardware VTEP databaseserver (for the hardware VTEP database) vis-à-vis the lock: lockrequest, lock steal request, and lock release. Lock request is a requestto obtain the lock for a data record in order to read and/or write tothe data record. When another database client has a lock for the datarecord, a lock request does not cause the database server to remove thelock from the other database client to provide the lock to the databaseclient that requested the lock. A lock steal request, however, doescause the database server to remove the lock from another databaseclient that currently has the lock in order to provide the lock to thedatabase client that provided the lock steal request. When a databaseclient is done with a lock, it provides a lock release command to thedatabase server to release the lock.

Some embodiments create a lock for a logical switch record in theLogical_Switch table. Once the binding in the vlan_bindings column isestablished and the lock is created, a database client on the MHFEacquires a lock for the logical switch by providing the logical switch'sidentifier along with the lock request to the MHFE's hardware VTEPdatabase server. Subsequently, when the controller wishes to change thelogical switch's configuration (e.g., the logical switch's control planedata records), the controller's hardware VTEP database client provides alock steal request and the logical switch's identifier to the databaseserver.

The MHFE's database server provides a notification to its databaseclient that the lock has been stolen, which indicates a forthcomingchange to the forwarding information. The MHFE's database client triesto re-acquire the lock. However, its attempts fail as long as thecontroller is holding the stolen lock while it makes changes. Theforwarding plane continues to work according to the forwardinginformation of the last transaction, i.e., there is no outage. After thecontroller is done with making its changes, it releases the lock for thelogical switch. At this point, the MHFE's database client's lockre-acquisition operation succeeds. When the MHFE database client is ableto re-acquire the lock, it applies all the changes that the controllermade to the forwarding table to its forwarding plane. Thus, in thismanner, the forwarding plane for the logical switch is transactionallyupdated in some embodiments.

Instead of using the lock-based approach, other embodiments define aconfiguration data tuple that the controller uses to explicitly informthe MHFE that the control plane configuration data is being updated andhence might not provide a consistent view of a logical forwardingelement or a logical network. For instance, instead of using thelock-based approach, some embodiments change the hardware VTEP schema toadd a Boolean column to the Logical_Switch table to indicate whether thelogical switch's information in the hardware VTEP database is consistentfrom the controller's point of view. This column is referred to below asthe state_consistent column. FIG. 2 illustrates such a modifiedLogical_Switch table 200 with a state_consistent column 205.

In some embodiments, the controller initializes this column to Falsewhile creating a logical switch. The controller is free to update thevlan_bindings column of the Physical_Port table at any point for thislogical switch. After supplying all the data tuples for the logicalswitch (e.g., all the data tuples to the Ucast_Macs_Remote table,Mcast_Macs_Remote table, and Physical_Port table), the controllerupdates the state_consistent column to True. Once that happens, the MHFEdatabase client modifies the MHFE's forwarding tables in the data planebased on the supplied logical switch configuration tuples.

When the controller wants to modify the MHFE's control planeconfiguration for an existing logical switch, the controller firstchanges the state_consistent column 205 to False. The MHFE agentmonitors this column. When the column becomes False, the MHFE'sforwarding records in the data plane continue to work in its lasttransactional state. The controller makes the changes to the MHFE'shardware VTEP database, and then changes the state_consistent column toTrue. At this point, the MHFE's database client applies all changes toits forwarding records in the data planes.

The above-described transactional control techniques will be furtherdescribed below by reference to FIGS. 5-9. However, before describingthese figures, the network control system of some embodiments will befurther described below by reference to FIGS. 3 and 4.

FIG. 3 illustrates a network control system 300 that implements the MHFEmanagement methods of some embodiments of the invention. In this system,the MHFE is a TOR switch 302 that communicatively couples data computenodes (e.g., VMs, containers, etc.) that execute on host computers in ashared public network, with standalone or virtualized servers in aprivate network. In this example, the public network includes two racks350 and 352 that include a plurality of VMs that execute on shared hostcomputers. The two racks have two TORs 306 and 308. The private networkincludes a rack 354 that includes virtualized and non-virtualizedservers. One of ordinary skill will realize that in other examples thedata compute nodes in the private network do not reside in a rack or ina single rack. Also, in some embodiments, the private and public networkcompute nodes can reside in the same datacenter (i.e., same physicallocation), or they can reside in different datacenters (i.e., indifferent locations).

The TOR 302 implements a logical switch to connect the servers in theprivate network (i.e., in the rack 354) to the VMs in the publicnetwork. As shown, the servers of the public racks 350 and 352 executeSFEs (e.g., a software switch and/or router) in addition to the VMs.These SFEs are configured by a cluster of physical controllers 330 and acluster of logical controllers 335 to form multiple logical networks,each with one or more logical switches and routers. The logical networksisolate the data message communication of the different sets of VMs fromeach other, in order to allow the different sets of VMs for differentlogical networks to operate securely on the same and/or different hosts.

In some embodiments, the host computers in the same public network rackor in two different public network racks can connect to one anotherthrough one or more tunnels 312 that allow the LFEs of the logicalnetworks to be formed as logical overlay forwarding elements. The tunnelheaders in some embodiments include logical network identifiers (e.g.,VNIs) that are needed to uniquely identify the LFEs. Different types oftunnels can be used in different embodiments. Examples of such tunnelsinclude STT (stateless transport tunnels), GRE (Generic RoutingEncapsualtion) tunnels, VXLAN tunnels, Geneve tunnels, etc. Tunnels canoften be viewed as point-to-point logical wire connections between theirendpoints (e.g., between a host and a TOR, or between two hosts) becausepackets inside the tunnel headers are transparent to the interveningnetwork fabric (e.g., intervening switches, routers, etc.).

In this environment, the network controllers 330 and 335 configure theTOR 302 to become part of a logical network formed by SFEs in the publicnetwork rack(s). These controllers, on the other hand, do not configurethe TORs 306 and 308 to be part of the logical networks. These TORs 306and 308 are treated as intervening network fabric. As shown, the TOR 302connects to the host computers in the public network racks 350 and 352through multiple logical overlay tunnels 314 for carrying the logicalnetwork identifiers for the logical network and for isolating thelogical network data messages from intervening public network fabric(e.g., from TORs 306 and 308 on the racks 350 and 352). By incorporatingthis TOR 302 into a logical network (e.g., into a logical switch for alogical network), the data messages from the VMs of the logical networkcan be directed to the ports of the TOR 302 for forwarding to DCNs(e.g., VMs and servers) in the private network rack 354.

The logical controllers generate data to define the logical forwardingelements, while the physical controllers distribute the generated datato the TOR 302 and SFEs. The number of logical controllers can bedifferent than the number of logical networks as one logical controllercan generate data for multiple logical networks. The generated data isused to configure the SFEs and TOR 302 to implement the logicalforwarding elements. In some embodiments, the generated data istransformed into physical data by the physical controllers 330, localcontrollers (not shown) executing on the hosts, and/or by a moduleoperating on the TOR 302, before this data is supplied to the forwardingplane of the SFEs and/or TOR 302. For instance, before distributing thedata generated by the logical controller, a physical controller in someembodiments converts the data into another format, e.g., into (1)physical control plane data for the TOR 302 and/or SFEs, or (2) into aformat that a TOR module or host local controller can further process toproduce physical control plane data.

The number of physical controllers can be different than the number ofmanaged TORs or SFEs as one physical controller typically distributesdata to multiple managed TORs or SFEs. Also, in some embodiments, onlyone physical controller is the master controller for supplying data to aset of managed forwarding elements (e.g., SFEs or MHFEs) to configurethe managed forwarding elements to facilitate the creation of LFEs. Atany given time, only the master physical controller can provide data toits managed forwarding elements. In some embodiments, each forwardingelement's master physical controller can have another physicalcontroller that operates as a slave physical controller that serves as abackup (e.g., a hot standby backup) to the master physical controller incase the master controller fails.

In some embodiments, one controller can operate as both a logicalcontroller and a physical controller. Each controller in someembodiments is a separate software process, and one computing device canexecute two controller processes, where one controller process is alogical controller and another controller process is a physicalcontroller. To communicate with the managed TORs, each physicalcontroller has a TOR agent 340 to communicate with the TORs for whichthe physical controller is the master controller (i.e., the primarycontroller for communicating with the TORs). In some embodiments, themanaged TORs and TOR agents communicate with each other by using theOVSdb protocol. In some embodiments, the TOR agents employ thetransactional boundary controls of some embodiments to ensure that theyprovide configuration data in a transactional manner to create LFEs orto update LFEs. In some embodiments, the controllers (e.g., the logicaland physical controllers 330 and 335) communicate through RPC (remoteprocedure call) channels.

In some embodiments, the network controller cluster defines each logicalnetwork by configuring the software and hardware forwarding elements(e.g., TOR switches). To configure such switches, some embodimentsimplement database servers on software and hardware forwarding elements.The network controller cluster then communicates with the databaseservers to provide data for configuring these software and hardwareforwarding elements to implement logical forwarding elements.

FIG. 4 illustrates how a network controller cluster 400 communicateswith a managed software switch 405 and a managed hardware switch 410(e.g., a TOR) in some embodiments. In this example, each of the switcheshas an OVSdb server 415 and 420 with which the network controllercluster 400 communicates by using the OVSdb protocol. The softwareswitch 405 is an OVS (Open Virtual Switch) switch that executes on ahost computer 425. As shown, the software switch 405 has a databaseserver 415, an OVS database 430, an OpenFlow agent 432, and a forwardingmodule 434. In the discussion below, the flow agent 432 may be referredto as an OVS daemon, and the forwarding module 434 may be referred to asa kernel module. As further shown, the hardware switch 410 includes adatabase server 420, an OVS database 438, a software stack 440, a switchASIC 444, ingress and egress ports 446 and 448, and forwarding tables450. The software stack 440 has a database client 452.

The network controller cluster 400 also has OVSdb clients 460 tointeract with the OVSdb servers 415 and 420. In some embodiments, thenetwork controller cluster 400 includes logical controllers 335 andphysical controllers 330 with a TOR agent 340. In these embodiments, thephysical controller 330 has an OVSdb client to interact with the OVSdbserver 415 on the software switch 405, and this controller's TOR agenthas another OVSdb client to interact with the OVSdb server 420 on thehardware switch 410.

As shown, the network controller cluster 400 exchanges management datawith the OVSdb server 415 of the software switch 405 by using OVSdbprotocol, while exchanging configuration data with the OVS daemon 432 ofthe software switch by using the OpenFlow protocol. The networkcontroller cluster 400 exchanges management data and forwarding statewith the hardware switch 410 by using the OVSdb protocol.

In some embodiments, the host 425 includes hardware, a hypervisor, andone or more virtual machines (VMs). The hardware may include typicalcomputer hardware, such as processing units, volatile memory (e.g.,random access memory (RAM)), nonvolatile memory (e.g., hard disc drives,optical discs, etc.), network adapters, video adapters, or any othertype of computer hardware. The hardware can also include one or moreNICs (network interface controllers).

A hypervisor is a software abstraction layer that can run on top of thehardware of the host 425. There are different types of hypervisors,namely Type 1 (bare metal), which runs directly on the hardware of thehost, and Type 2 (hosted), which run on top of the host's operatingsystem. The hypervisor handles various management tasks, such as memorymanagement, processor scheduling, or any other operations forcontrolling the execution of the VMs. Moreover, the hypervisorcommunicates with the VMs to achieve various operations (e.g., settingpriorities). In some embodiments, the hypervisor is a Xen hypervisorwhile, in other embodiments, the hypervisor may be any other type ofhypervisor for providing hardware virtualization of the hardware on thehost 425.

In some embodiments, the software switch 405 runs on a VM. The VM can bea unique virtual machine, which includes a modified Linux kernel (e.g.,to include the OVS kernel module 434). The VM of such embodiments isresponsible for managing and controlling other VMs running on thehypervisor. In some embodiments, the VM includes a user space and theOVS daemon runs as a background process in the user space.

The OVS daemon 432 is a component of the software switch 405 that makesswitching decisions. On the other hand, the kernel module 434 receivesthe switching decisions, caches them, and uses them subsequently toprocess packets. For instance, when a packet comes in, the kernel module434 first checks a datapath cache to find a matching flow entry. If nomatching entry is found, the control is shifted to the OVS daemon 432.The OVS daemon 432 examines one or more flow tables to generate a flowto push down to the kernel module 434. In this manner, when anysubsequent packet is received, the kernel module 434 can quickly processthe packet using the cached flow entry. The kernel module 434 provides afast path to process each packet.

Network controller 400 uses the OpenFlow protocol to inspect and modifya set of one or more flow tables managed by the OVS daemon 432. Thenetwork controller cluster 400 computes flows and pushes them to thesoftware switch 405 through this OpenFlow channel. The networkcontroller communicates with the database server 415 of the softwareswitch 405 by using the database protocol. Through these communications,the network controller can push configuration data for creating andmanaging overlay tunnels to transport nodes. The network controllermight also use OVSdb protocol for discovery purposes (e.g., discoverwhich virtual machines are hosted at the hypervisor). The OVS daemon 432also communicates with the database server 415 to access management data(e.g., bridge information, virtual interfaces information) stored in thedatabase 430.

Unlike its communication with the software switch 405, the networkcontroller 400 communicates with the hardware switch 410 by just usingthe OVSdb protocol. The database protocol is essentially used to controlthe hardware switch 410. Through the database channel, the networkcontroller reads the configurations from the hardware switch (e.g., aninventory of its physical ports) and sends management data to thehardware switch. For example, the network controller 400 can sendinstructions to the hardware switch to create tunnel ports for a logicalswitch. Also, when the network controller exchanges forwarding state(e.g., L2 and/or L3 forwarding state) with the hardware switch 410, thenetwork controller can instruct the hardware switch 410 to program itsforwarding table using the database protocol.

The hardware switch's ingress ports 446 are a set of ports through whichthe hardware switch 410 receives network data. The ingress ports 446 mayinclude different numbers of ingress ports in different embodiments. Asshown, the ingress ports 446 receives network data that is external tothe switch 410. Packets received through the ingress ports are processedby the switch's ASIC 444.

The switch ASIC is a component, which is specifically designed tosupport in-hardware forwarding. That is, it is primarily designed toquickly forward packets. To simplify the description, only one switchingASIC is shown. However, one of ordinary skill in the art wouldunderstand that the hardware switch 410 could include a number of ASICsthat operate in conjunctions with one another to forward packets.

The ASIC 444 processes the packets that it receives by using the flowentries in its forwarding tables 450. In some embodiments, theforwarding tables 450 store active flow tables and/or flow entries thatare used to determine operations for making switching decisions. In thisexample, each flow entry includes a qualifier and an action. Thequalifier defines a set of fields to match against a set of packetheader fields. As shown, the flow entries are stored in memory. Thememory can be random access memory (RAM) or some other type of memorysuch as Content Addressable Memory (CAM) or Ternary Content AddressableMemory (TCAM). For example, a vendor may design their Layer 2 switcheswith CAM for performing Layer 2 switching and/or with TCAM forperforming Quality of Service (QoS) functions. The switch architecturemay support the ability to perform multiple lookups into multipledistinct CAM and/or TCAM regions in parallel. The CAM and TCAM areexamples of switching ASICs that some vendors' switches leverage forline-speed fast switching.

After processing the packet, the ASIC 444 supplies the packet to one ofthe egress ports 448. The egress ports 448 represent a set of portsthrough which the switching element 410 sends network data. The egressports 448 may include different numbers of egress ports in differentembodiments. In some embodiments, some or all of the egress ports 448may overlap with some or all of the ingress ports 446. The ports 446 and448 along with the ASIC 444 and forwarding tables 450 compose the dataplane datapath of the hardware switch 410. The flow entries in theforwarding tables 450 represent the data plane records of the hardwareswitch 410, while the database records in the OVS database 438 representthe control plane records of the hardware switch 410.

The OVSdb server 420 controls access to the database 438. Through thisserver 420, the database client 452 accesses the database 438 to readand write data. In addition, through the OVSdb server 420, the OVSdbclient 460 on the network controller 400 accesses the database 438 toread and write data (e.g., management data and forwarding state). Insome embodiments, the database server 420 may send a notification to onedatabase client (e.g., on the switch end) if the other database client(e.g., on the network controlled end) updates a table or a subset of atable of the database 438. In some embodiments, the database protocolspecifies a monitor call, which is a request, sent from a databaseclient (452 or 460) to the database server 420, to monitor one or morecolumns of a table and receive updates when there is an update to theone or more columns (e.g., a new row value, an update to an existing rowvalue, etc.).

For example, when the client 460 on the network controller 400 makes anupdate to database 438 through the OVSdb server 420, the OVSdb server420 in turn generates a notification for the hardware switch's client452. The client 452 may then read the update, and have its associatedsoftware stack 440 program the forwarding tables 450 of the switch ASIC444. Another example is when the database client 452 on the switch'ssoftware stack 440 updates the database 438 (through the server 420)with MAC addresses of a machine that is connected to its port. Thiswould in turn cause the database server 420 to send a notificationregarding the update to the client 460 on the network controller 400.

In some embodiments, the database server 420 does not notify the OVSdbclient 452 of the creation of a logical forwarding element data setuntil the vlan_binding column for the logical forwarding element hasbeen defined. Alternatively, in embodiments that define astate_consistent tuple for the logical forwarding element, the databaseserver 420 does not notify the OVSdb client 452 of updates to therecords for a logical forwarding element after the state_consistenttuple is changed from True to False, until this tuple is changed back toTrue.

In some embodiments, the database server 420 is designed to handletransactions and deal with conflicts with multiple writers (e.g., whenmore than one OVSdb client tries to write to the OVS database 438). Thedatabase server 420 is also designed to provide asynchronousnotifications. For example, when there is an update to a database table,the database server 420 sends a notification regarding an update to aclient (e.g., executing on a network controller or on the hardwareswitch). In some embodiments, the database server 420 defines a lock foreach logical forwarding element, and processes lock requests, lock stealrequests and lock releases from the network controller's OVSdb client460 and hardware OVSdb client 452.

The switch software stack 440 represents several programs that operateon the hardware switch 410. The software stack 440 can include a varietyof different programs to configure and manage the switch 410. This caninclude management that is in and outside of the scope of the networkcontroller cluster. For instance, the software stack 440 may include aprogram to update its firmware, modify switch settings (e.g., itsadministrative password), and/or reset the switch. The software stack440 is vendor specific, which means that it can change from onehardware-switch vendor to another hardware-switch vendor. Accordingly,different vendors might provide different features that are representedby their corresponding software stack 440.

The software stack 440 includes at least one module to program theswitch ASIC 444 and update the forwarding plane records based on controlplane records retrieved from the OVS database 438. The software stack440 updates the data plane records (e.g., forwarding records in theforwarding table 450) using any number of known techniques. Differentswitch vendors use different techniques to update data plane recordsbased on the retrieved control plane records.

FIG. 5 illustrates a process 500 that a physical controller performs insome embodiments to supply the definition of a logical forwardingelement to an MHFE in a transactional manner. In this example, the TORagent of the physical controller performs this process to deploy alogical switch on a TOR in a transactional manner. Many of theembodiments described below by reference to FIGS. 6-9 are also describedby reference to operations of TORs and the creation of logical switches.However, one of ordinary skill will realize that other embodimentsperform analogous processes to define other types of logical forwardingelements and/or to deploy logical forwarding elements on different typesof MHFEs.

As shown, the process 500 initially receives (at 505) the definition ofa logical switch that needs to be deployed on a TOR. Next, the process500 selects (at 510) a table to update in the TOR's OVS database 438other than the Physical_Port table. Examples of such tables include theUcast_Macs_Remote table, the Mcast_Macs_Remote table and theLogical_Switch table. At 515, the process 500 sends to the TOR's OVSdbserver 420 one or more packets that contain data for defining one ormore records in the selected table (i.e., the table selected at 510) forthe logical switch. Examples of such records include the logical switchrecord in the Logical_Switch table 115, MAC records in the Ucast table105, and service node records in the Mcast table 110, as described aboveby reference to FIG. 1.

Next, at 520, the process 500 determines whether it has pushed the datafor all the OVS database tables except the Physical_Port table to theTOR's OVSdb server 420. If not, the process 500 returns to 510 to selectanother OVSdb table other than the Physical_Port table, and then to 515to push data records for this newly selected table to the TOR's OVSdbserver 420. For some embodiments, the illustration of the determinationoperation 520 is conceptual as in these embodiments the TOR agentselects the OVSdb tables according to a fixed order, in which thePhysical_Port table is last.

Once the process 500 determines (at 520) that it has processed all theOVSdb tables except for the Physical_Port table, the process determines(at 525) whether it has received confirmation from the OVSdb server 420that it has created and/or populated the appropriate records in the OVSdatabase 438 with the data that the process 500 send at 515. If not, theprocess 500 remains at 525 until it has received the requiredconfirmations. In some cases, the process 500 resends data for an OVSdbtable when it does not receive the required confirmation for this table.

Once the process 500 determines (at 525) that it has receivedconfirmations for all the OVSdb tables for which it has pushed data tothe TOR, the process transitions to 530. In other embodiments, theprocess 500 does not check (at 525) to see whether it has receivedconfirmations from the OVSdb server 420 that is has created and/orpopulated the appropriate records in the OVS database 438 based on thedata provided by the process 500. Instead, in these embodiments, theprocess 500 transitions to 530 when it determines (at 520) that it hasthe data for the Physical_Port table to process.

At 530, the process 500 sends the VLAN binding tuple or tuples for thePhysical_Port table to the OVSdb server 420. The process 500 remains at530 until it receives confirmation from the OVSdb server 420 that it hasprocessed the VLAN binding tuples. Once the process 500 receives thisconfirmation, it ends. Again, the process 500 in some embodiments doesnot wait for confirmation from the OVSdb server 420, and just ends afterit sends the VLAN binding tuple or tuples for the Physical_Port table.

The process 500 pushes (at 530) the VLAN binding tuples last in order toprevent the hardware switch's OVSdb client 452 from updating theforwarding tables 450 until all of the logical switch's records havebeen specified in the OVS database 438. In some embodiments, the OVSdbserver 420 does not notify the OVSdb client 452 of changes to the OVSdatabase 438 relating to a logical switch until the VLAN binding columnis populated. Hence, by delaying pushing the VLAN binding tuples, theprocess 500 can prevent the OVSdb client 452 from updating theforwarding plane until the process has pushed all the control planerecords for the logical switch to the hardware switch.

FIG. 6 illustrates a process 600 that a hardware switch's OVSdb server420 performs to define a logical switch on the hardware switch. Asshown, this process starts when the OVSdb server 420 receives (at 605)data tuples from the process 500 of the network controller (e.g., TORagent) for the logical switch. These data tuples include tuples for theOVSdb tables that need to have records for the logical switch to bedefined on the hardware switch. These tables include theUcast_Macs_Remote table 105, the Mcast_Macs_Remote table 105 and theLogical_Switch table 115. The received data tuples (at 605) do notinclude data tuples for the Physical_Port table 120.

At 605, the process 600 creates the records and/or populates previouslycreated records in these tables based on the received data tuples. At610, the process 600 then sends confirmation to the process 500 of thenetwork controller of its processing of the received data tuples (i.e.,of its creation or population of the data records). To avoid obscuringthe description of the process 600 with unnecessary detail, FIG. 6illustrates that the process 600 supplies confirmations for allnon-Physical_Port table tuples at once after receiving all of these datatuples. One of ordinary skill will realize that in some embodiments theprocess 600 supplies a confirmation for each set of such tuples (e.g.,for each set of tuples for a table) after processing that set of tuples.

Once the process 600 has provided (at 610) confirmation of processing ofall the received data tuples, the process receives (at 615) theVLAN-binding tuple(s) for the logical switch. The process 600 thenrecords the received VLAN-binding tuple(s) in the vlan_bindings columnof the Physical_Port table. As populated, each VLAN binding tuple in thevlan_bindings column of the Physical_Port table binds a specific VLAN ona specific physical port of the hardware switch to the logical switch.In some embodiments, the process 600 receives only one VLAN-bindingtuple for each logical switch for the hardware switch, because in theseembodiments each logical switch can bind to at most one VLAN binding ofa physical port. In other embodiments, however, the process can receivemore than one VLAN-binding tuple for each logical switch for thehardware switch, because in these embodiments each logical switch canbind to more than one VLAN binding of a physical port or to more thanone port.

After storing (at 615) the received VLAN-binding tuple(s) in thePhysical_Port table, the process 600 creates (at 620) a lock for thelogical switch. In the embodiments that do not utilize a lock formodifying a logical switch's configuration on a hardware switch, no lockis defined at 620. On the other hand, in the embodiments in which thecontroller needs a lock to modify the logical switch's records, thecontroller can steal the logical switch's lock, in order to prevent thehardware switch's OVSdb client from modifying the data plane recordsbased on control plane records that the controller has not been able tofully update. In some embodiments, the process 600 creates a lock forthe logical switch at the request of the process 500 of the networkcontroller. Specifically, in these embodiments, the configuration dataprovided by the network controller includes a request to create a lockfor the logical switch. In other embodiments, the process 600 of theOVSdb server is pre-configured to create locks for logical switches, andhence does not need to be directed to do this by the network controller.

Next, at 625, the process 600 sends a confirmation to the TOR agent thatit has processed the VLAN-binding tuple(s), and created the logicalswitch. In some embodiments, the process 600 also provides (at 625) alogical switch name and/or this switch's lock name or attribute to theprocess 500 so that the network controller (e.g., the TOR agent) willhave a handle for requesting the lock for a subsequent logical switchupdate. In other embodiments, the process 600 does not provide to theprocess 500 the logical switch's name/attribute as the controlleroperates on an assumption that the logical switch has a lock.

After providing (at 625) the confirmation to the process 500, theprocess 600 notifies (at 630) the TOR's OVSdb client 452 of the creationof records in the OVS database 438 for the new logical switch. At thispoint, the OVSdb client 452 begins to access the OVS database 438through the OVSdb server 420, in order to update the TOR's forwardingplane records (e.g., forwarding tables 450). After 630, the processends.

As described above, the MHFEs in some embodiments contain configurationdatabases and execute database servers with which the networkcontrollers can interact through a database protocol. The databaseprotocol of some embodiments provides a lock operation to lock or unlockan LFE's records in an MHFE's configuration database. The lock operationallows the network controller to steal the lock in order to prevent anMHFE database client from obtaining the lock and reading the LFE'srecords in the configuration database, while the controller writes tothe configuration database. The lock feature resolves conflicts bymaking the MHFE agent receive the lock, and hence receive permission,before it can read the LFE's records in the database.

More specifically, in some embodiments, a controller must obtain a lockfor an LFE from the MHFE's database server before the controller canmodify the LFE's records in the database. In some embodiments, thecontroller obtains the lock through a steal request in order (1) to beable to get the lock irrespective of whether the MHFE database clientcurrently has the lock and (2) to be able to block the MHFE databaseclient from getting back the lock. Similarly, an MHFE database clientmust obtain a lock for an LFE from the MHFE's database server beforethis client can read the LFE's records in the database. When thecontroller has stolen the lock, the WIFE database client cannot obtainthe lock through a lock request until the controller releases the lock.After receiving a lock release from the controller, the database serverprovides the lock to the WIFE agent so that it can then read the LFE'srecords in the database.

FIG. 7 illustrate a process 700 that the TOR agent, OVSdb server 420 andthe OVSdb client 452 perform in some embodiments during and after aperiod in which the TOR agent modifies the records of a logical switchin the OVS database 438. As shown, the process 700 starts when the TORagent receives (at 702) updates to one or more of the logical switch'sdata tuples from the logical controller 335 for the logical switch.

Next, at 704, the OVSdb client 460 of the TOR agent 340 provides a locksteal request for the logical switch to the OVSdb server 420 of the TOR.In some embodiments, the OVSdb client 460 first provides a lock requestto the OVSdb server 420, and if it is told that the lock currentlyresides with the TOR's OVSdb client 452, then provides a lock stealrequest to the OVSdb server 420. In other embodiments, however, theOVSdb client 460 just provides a lock steal request without firstproviding a lock request and having this lock request rejected, asillustrated in FIG. 7.

After receiving (at 706) this request, the OVSdb server 420 sends (at708) a notification to the TOR's OVSdb client 452 that it has lost thelock. As shown, prior to receiving this notification (at 736), the TOR'sOVSdb client 452 in this example had obtained the lock (at 734) so thatit could access the OVS database 438.

After notifying the OVSdb client 452 that it no longer has the lock forthe logical switch, the OVSdb server 420 provides (at 708) this lock tothe TOR agent's OVSdb client 460. Upon receiving (at 710) the lock forthe logical switch, the OVSdb client 460 sends (at 712) one or morelogical-switch update data tuples to the OVSdb server 420. Based on theupdate data tuples, the OVSdb server 420 modifies (at 714) one or morelogical switch's records in the OVS database 438.

Once the OVSdb server 420 has received and processed all update datatuples from the TOR agent's OVSdb client 460, the OVSdb server 420provides (at 714) a confirmation to the OVSdb client 460 that it hasprocessed all of the update data tuples. After receiving (at 712) thisconfirmation, the TOR agent's OVSdb client 460 sends (at 716) a lockrelease command to the OVSdb server 420 so that it can relinquish thelogical switch's lock. At 718, the OVSdb server 420 receives the lockrelease.

During the period in which the TOR agent's OVSdb client 460 has acquiredthe lock for the logical switch, the TOR's OVSdb server 420 does notrespond to any lock request from the TOR's OVSdb client 452 for thelogical switch. FIG. 7 pictorially illustrates a lock request 738 by theOVSdb client 452. As shown, the OVSdb server 420 does not respond tothis lock request while the TOR agent has acquired the lock for thelogical switch. In some embodiments, the OVSdb server 420 affirmativelyrejects a lock request from the OVSdb client 452 while the TOR agent hasacquired the logical switch's lock, instead of just not responding tosuch a request.

After the OVSdb server receives (at 718) the lock release from the TORagent, the OVSdb server supplies (at 720) a notification to the TOR'sOVSdb client 452 of the changes to the logical switch's records in theOVS database 438. At 720, the OVSdb server also provides the lock forthe logical switch to the TOR's OVSdb client 752. The OVSdb client 752receives (at 722) the lock release and change notification, and inresponse, directs (at 724) the OVSdb server to supply the updatedlogical switch records to it.

While the example illustrated in FIG. 7 shows the OVSdb server 420providing both the lock and change notification at 720, the OVSdb server420 of some embodiments only provides the lock at 720. In theseembodiments, when the OVSdb client 452 automatically checks for changesto the logical switch records when it obtains the lock. Also, in someembodiments, the OVSdb server 420 just provides the change notificationat 720. In response to this notification, the OVSdb client 452 then asksthe OVSdb server for the lock before asking the OVSdb server for thelogical switch's records.

In the example illustrated in FIG. 7, the OVSdb server receives (at 726)the request for the logical switch's records, and provides (at 728) theupdated logical switch records to the TOR's OVSdb client 752. At 730,the OVSdb client then modifies the forwarding plane records (e.g., therecords in the forwarding tables 450) based on the received logicalswitch records. In some embodiments, the TOR's OVSdb client 752 providesa confirmation of recording these updates to the OVSdb server. In otherembodiments, the client does not provide such a confirmation.

After updating the forwarding plane records, the OVSdb clientrelinquishes the lock and the process 700 then ends. In someembodiments, the OVSdb client does not relinquish the lock for thelogical switch even after updating the forwarding plane records for thelogical switch based on a control plane update for the logical switch.In these embodiments, the OVSdb server affirmatively takes away the lockfrom the TOR's OVSdb client 452 once the TOR agent's OVSdb client 460wants to modify the logical switch's control plane records.

FIG. 7 illustrates the OVSdb server 420 as sending (at 720) one updatenotification to the TOR's OVSdb client 452 once the TOR agent hascompleted its control plane update for the logical switch. In otherembodiments, the OVSdb server 420 or some other notification processassociated with the OVS database 438 notifies the TOR's OVSdb client 452with multiple update notifications while the TOR agent is updatingmultiple data tuple sets associated with the logical switch. In theseembodiments, the TOR's OVSdb client 452 repeatedly attempts to obtainthe logical switch's lock in response to the various differentnotifications, but these attempts are unsuccessful while the TOR agent'sOVSdb client 460 has not released the lock.

In some embodiments, the OVSdb server 420 provides a logical switch'slock to the TOR agent's OVSdb client 460 anytime that this client asksfor the lock. Other embodiments, however, place some restriction on theTOR agent's OVSdb client 460 obtaining the switch's lock. For instance,after the OVSdb client 460 has supplied one set of updates to thelogical switch's control plane records and has relinquished the logicalswitch's lock, the OVSdb server 420 does not allow this client 460 toreacquire the logical switch's lock while the TOR OVSdb client 452 isupdating the TOR's forwarding plane records in view of the suppliedcontrol plane updates. In these embodiments, the OVSdb server 420 onlyallows the TOR agent's OVSdb client 460 to reacquire the logicalswitch's lock after receiving a confirmation from the TOR's OVSdb client452 that it has processed all of the updates supplied by the TOR agent.

FIG. 8 illustrates a process 800 that a TOR agent performs in someembodiments to define a logical switch or to modify a logical switchdefinition in a transactional manner for a TOR by using astate_consistent tuple 205 for the logical switch. As shown, thisprocess initially (at 805) receives the definition of a logical switchthat needs to be deployed on a TOR, or receives a modification to thedefinition of a previously defined logical switch that has already beendeployed on the TOR. When the logical switch is a new logical switchthat is being deployed on the TOR, the process sends (at 810) one ormore packets to the TOR's OVSdb server 420 to create a record for thislogical switch in in the logical switch table 200, and to set thestate_consistent value in this record for the logical switch to False.

On the other hand, when the logical switch was previously deployed onthe TOR, the process sends (at 810) one or more packets to the TOR'sOVSdb server 420 to direct it to change the state_consistent value ofthe logical switch to False in the logical switch table 200. Changingthis state to False prevents the TOR's OVSdb client 452 from accessingthe OVS database records for this logical switch. In some embodiments,when this state is False, the TOR's OVSdb server 420 ignores or rejectsthe TOR's OVSdb client's 452 requests for access to the records in theOVS database 438 that relate to the logical switch.

At 815, the process 800 selects a table to update in the TOR's OVSdatabase other than the Logical_Switch table. Examples of such tablesinclude the Ucast_Macs_Remote table, the Mcast_Macs_Remote table and thePhysical_Port table. At 820, the process sends to the TOR's OVSdb server420 one or more packets that contain data for defining one or morerecords in the selected table (i.e., the table selected at 815) for thelogical switch. Examples of such records include the logical switchrecord in the VLAN_bindings for the Physical_Port table 120, MAC recordsin the Ucast table 105, and service node records in the Mcast table 110,as described above by reference to FIG. 1.

Next, at 825, the process 800 determines whether it has pushed to theTOR's OVSdb server 420 the data for all the OVS database tables otherthan the Logical_Switch table. If not, the process 800 returns to 815 toselect another OVSdb table other than the Logical_Switch table, and thento 820 to push data records for this newly selected table to the TOR'sOVSdb server 420. For some embodiments, the illustration of thedetermination operation 820 is conceptual as in these embodiments theTOR agent selects the OVSdb tables according to a fixed order, in whichthe Logical_Switch table is last.

Once the process 800 determines (at 825) that it has processed all theOVSdb tables other than the Logical_Switch table, the process 800determines (at 830) whether it has received confirmation from the TOR'sOVSdb server 420 that it has created and/or populated the appropriaterecords in the OVS database 438. If so, the process 800 transitions to835. If not, the process 800 remains at 830 until it has received therequired confirmations. In some cases, the process 800 resends data foran OVSdb table when it does not receive the required confirmation forthis table. Also, in some cases, the process 800 does not wait forconfirmation from the OVSdb server 420 that it has processed thepreviously supplied data tuples. In these embodiments, the process 800simply transitions from 825 to 835 when it determines that it hasprocessed all the OVSdb tables other than the Logical_Switch table.

At 835, the process directs (at 835) the TOR's OVSdb server 420 tochange the state_consistent tuple in the Logical_Switch table 200 toTrue. When the logical switch's record in this table has to be modified,the process 800 in some embodiments also sends (at 835) other datatuples to change other parameters in the Logical_Switch table for thelogical switch. In some embodiments, the process 800 sends such otherdata tuple(s) before changing the state_consistent tuple to True. Inother embodiments, the process 800 sends the other logical_switchtuple(s) for changing a pre-existing logical_switch's record in thetable 200 at 810, instead of 835.

The process 800 remains at 835 until it receives confirmation from theTOR that it has changed the state_consistent tuple to True for thelogical switch. Once the process receives this confirmation, it ends.The process 800 changes the state_consistent tuple to True last in orderto prevent the OVSdb client 452 from updating the forwarding tables 450until all of the logical_switch's records have been specified/modifiedin the OVS database 438. In some embodiments, the OVSdb server 420 doesnot notify the OVSdb client 452 of changes to the OVS database 438relating to a logical switch until the state_consistent tuple is changedfrom False to True. In other embodiments, the OVSdb client 452 receivesnotifications of changes to the OVS database 438 relating to a logicalswitch even when the state_consistent tuple is False. However, whilethis value is False, the OVSdb server 420 ignores or rejects allrequests by the OVSdb client 452 for access to records in the OVSdatabase 438 relating to the logical switch. In either of theseapproaches, by delaying pushing the state_consistent tuple, the process800 can prevent the OVSdb client 452 from updating the forwarding planeuntil the process has pushed all the control plane records ormodifications for the logical_switch to the TOR.

FIG. 9 illustrates a process 900 that a hardware switch's OVSdb server420 performs to create a logical switch on the hardware switch, or toupdate the configuration of a previously created logical switch on thehardware switch. This process starts when it OVSdb server 420 receives(at 905) from the network controller data tuples for the logical switchto the OVSdb server 420. When the logical switch was previously created,the process 900 initially receives (at 905) a request from the process800 to change the logical switch's state_consistent tuple to False. Inresponse, the process 900 (at 910) changes this tuple to False in theLogical_Switch table 200, sends a notification to the hardware switch'sOVSdb client 452 of this changed state, and then sends a confirmation ofthis change to the process 800 (i.e., to the TOR agent of the networkcontroller).

On the other hand, when the logical switch was not previously created,the process 900 receives (at 905) one or more data tuples to create arecord for this logical switch in in the logical switch table 200, andto set the state_consistent value in this record for the logical switchto False. In response, the process 900 (at 910) creates a record in theLogical_Switch Table 200 for the logical switch, sets thestate_consistent tuple in this record to False, and then sends aconfirmation of the creation of the record to the process 800 (i.e., tothe TOR agent of the network controller).

At 915, the process 900 receive data tuples from the process 800 of thenetwork controller (e.g., TOR agent) for the logical switch. These datatuples include tuples for the OVSdb tables that need to have records forthe logical_switch to be defined on the hardware switch. These tablesinclude the Ucast_Macs_Remote table 105, the Mcast_Macs_Remote table 110and the Physical_Port table 120. These data tuples (received at 915) donot include data tuples for the Logical_Switch table 115.

At 915, the process creates the records and/or populates previouslycreated records in these tables based on the received data tuples. At920, the process then sends confirmation to the process 800 of thenetwork controller of its processing of the received data tuples (i.e.,of its creation or population of the data records in the nonLogical_Switch tables of the OVS database 438 for the logical_switch).To avoid obscuring the description of the process 900 with unnecessarydetail, FIG. 9 illustrates that the process 900 supplies a confirmationfor all non-Logical_Switch table tuples at once after receiving all ofthese data tuples. One of ordinary skill will realize that in someembodiments the process 900 supplies a confirmation for each set of suchtuples (e.g., for each set of tuples for a table) after processing thatset of tuples.

Once the process 900 has provided confirmation of processing of all thereceived data tuples, the process (at 925) receives a data tuple tochange the state_consistent tuple to True and change this state to True.When the logical switch's record in this table has to be modified, theprocess 900 in some embodiments also receives (at 925) other data tuplesto change other parameters in the Logical_Switch table for the logicalswitch. In some embodiments, the process 900 receives such other datatuple(s) and processes these data tuples (e.g., changes records in thedatabase tables based on these tuples) before changing thestate_consistent tuple back to True. In other embodiments, the process900 receives the other logical switch tuple(s) for changing apre-existing logical switch's record in the table 200 at 905 instead of925, and it changes the Logical_Switch table 200 tuple(s) at 910 insteadof 925.

After storing (at 915) the received data tuple(s) in the Logical_Switchtable, the process 900 sends (at 920) a confirmation to the process 800that it has processed the tuple(s) Logical_Switch table. When thelogical switch was not previously created, this confirmation alsoinforms the process 800 of the creation of the logical switch. In someembodiments, the process 900 also provides (at 920) a logical switchname to the process 800 so that the network controller (e.g., the TORagent) will have a handle for the logical switch. In other embodiments,the process 900 does not provide the logical switch's name to theprocess 800 as the controller has this switch's identifier.

Once the process 900 has made its change(s) to the Logical_Switch table200 at 925, the process sends a confirmation of its processing the datatuple(s) received at 925. After providing (at 925) the confirmation tothe process 800, the process 900 notifies (at 930) the TOR's OVSdbclient 452 of the creation of records in the OVSdb database 438 for thenew logical switch or of the change of state_consistent tuple to Truefor a previously created logical switch. At this point, the OVSdb client452 can begin to access the OVS database 438 through the OVSdb server420, in order to update the TOR's forwarding plane records (e.g.,forwarding tables 450). After 925, the process ends.

One of ordinary skill will realize that the approach illustrated inFIGS. 8 and 9 is just one way of using the state_consistent tuple tocreate/update a logical switch's records on a TOR. Other embodiments usethis data tuple differently. For instances, some embodiments do notfirst create the logical switch's record in the Logical_Switch table anddefine the state_consistent tuple in this record to False, when thelogical switch is being initially defined on a TOR. These embodimentsjust create the logical switch's record in the Logical_Switch tablelast. In some of these embodiments, the hardware VTEP schema is modifiedto allow the other tables (e.g., Ucast table 105 and Mcast table 110) tobe created before the logical switch's record is created in theLogical_Switch table 200.

Many of the above-described features and applications are implemented assoftware processes that are specified as a set of instructions recordedon a computer readable storage medium (also referred to as computerreadable medium). When these instructions are executed by one or moreprocessing unit(s) (e.g., one or more processors, cores of processors,or other processing units), they cause the processing unit(s) to performthe actions indicated in the instructions. Examples of computer readablemedia include, but are not limited to, CD-ROMs, flash drives, RAM chips,hard drives, EPROMs, etc. The computer readable media does not includecarrier waves and electronic signals passing wirelessly or over wiredconnections.

In this specification, the term “software” is meant to include firmwareresiding in read-only memory or applications stored in magnetic storage,which can be read into memory for processing by a processor. Also, insome embodiments, multiple software inventions can be implemented assub-parts of a larger program while remaining distinct softwareinventions. In some embodiments, multiple software inventions can alsobe implemented as separate programs. Finally, any combination ofseparate programs that together implement a software invention describedhere is within the scope of the invention. In some embodiments, thesoftware programs, when installed to operate on one or more electronicsystems, define one or more specific machine implementations thatexecute and perform the operations of the software programs.

FIG. 10 conceptually illustrates a computer system 1000 with which someembodiments of the invention are implemented. The computer system 1000can be used to implement any of the above-described hosts, controllers,and managers. As such, it can be used to execute any of the abovedescribed processes. This computer system includes various types ofnon-transitory machine readable media and interfaces for various othertypes of machine readable media. Computer system 1000 includes a bus1005, processing unit(s) 1010, a system memory 1025, a read-only memory1030, a permanent storage device 1035, input devices 1040, and outputdevices 1045.

The bus 1005 collectively represents all system, peripheral, and chipsetbuses that communicatively connect the numerous internal devices of thecomputer system 1000. For instance, the bus 1005 communicativelyconnects the processing unit(s) 1010 with the read-only memory 1030, thesystem memory 1025, and the permanent storage device 1035.

From these various memory units, the processing unit(s) 1010 retrieveinstructions to execute and data to process in order to execute theprocesses of the invention. The processing unit(s) may be a singleprocessor or a multi-core processor in different embodiments. Theread-only-memory (ROM) 1030 stores static data and instructions that areneeded by the processing unit(s) 1010 and other modules of the computersystem. The permanent storage device 1035, on the other hand, is aread-and-write memory device. This device is a non-volatile memory unitthat stores instructions and data even when the computer system 1000 isoff. Some embodiments of the invention use a mass-storage device (suchas a magnetic or optical disk and its corresponding disk drive) as thepermanent storage device 1035.

Other embodiments use a removable storage device (such as a floppy disk,flash drive, etc.) as the permanent storage device. Like the permanentstorage device 1035, the system memory 1025 is a read-and-write memorydevice. However, unlike storage device 1035, the system memory is avolatile read-and-write memory, such a random access memory. The systemmemory stores some of the instructions and data that the processor needsat runtime. In some embodiments, the invention's processes are stored inthe system memory 1025, the permanent storage device 1035, and/or theread-only memory 1030. From these various memory units, the processingunit(s) 1010 retrieve instructions to execute and data to process inorder to execute the processes of some embodiments.

The bus 1005 also connects to the input and output devices 1040 and1045. The input devices enable the user to communicate information andselect commands to the computer system. The input devices 1040 includealphanumeric keyboards and pointing devices (also called “cursor controldevices”). The output devices 1045 display images generated by thecomputer system. The output devices include printers and displaydevices, such as cathode ray tubes (CRT) or liquid crystal displays(LCD). Some embodiments include devices such as a touchscreen thatfunction as both input and output devices.

Finally, as shown in FIG. 10, bus 1005 also couples computer system 1000to a network 1065 through a network adapter (not shown). In this manner,the computer can be a part of a network of computers (such as a localarea network (“LAN”), a wide area network (“WAN”), or an Intranet, or anetwork of networks, such as the Internet. Any or all components ofcomputer system 1000 may be used in conjunction with the invention.

Some embodiments include electronic components, such as microprocessors,storage and memory that store computer program instructions in amachine-readable or computer-readable medium (alternatively referred toas computer-readable storage media, machine-readable media, ormachine-readable storage media). Some examples of such computer-readablemedia include RAM, ROM, read-only compact discs (CD-ROM), recordablecompact discs (CD-R), rewritable compact discs (CD-RW), read-onlydigital versatile discs (e.g., DVD-ROM, dual-layer DVD-ROM), a varietyof recordable/rewritable DVDs (e.g., DVD-RAM, DVD-RW, DVD+RW, etc.),flash memory (e.g., SD cards, mini-SD cards, micro-SD cards, etc.),magnetic and/or solid state hard drives, read-only and recordableBlu-Ray® discs, ultra density optical discs, any other optical ormagnetic media, and floppy disks. The computer-readable media may storea computer program that is executable by at least one processing unitand includes sets of instructions for performing various operations.Examples of computer programs or computer code include machine code,such as is produced by a compiler, and files including higher-level codethat are executed by a computer, an electronic component, or amicroprocessor using an interpreter.

While the above discussion primarily refers to microprocessor ormulti-core processors that execute software, some embodiments areperformed by one or more integrated circuits, such as applicationspecific integrated circuits (ASICs) or field programmable gate arrays(FPGAs). In some embodiments, such integrated circuits executeinstructions that are stored on the circuit itself.

As used in this specification, the terms “computer”, “server”,“processor”, and “memory” all refer to electronic or other technologicaldevices. These terms exclude people or groups of people. For thepurposes of the specification, the terms display or displaying meansdisplaying on an electronic device. As used in this specification, theterms “computer readable medium,” “computer readable media,” and“machine readable medium” are entirely restricted to tangible, physicalobjects that store information in a form that is readable by a computer.These terms exclude any wireless signals, wired download signals, andany other ephemeral or transitory signals.

While the invention has been described with reference to numerousspecific details, one of ordinary skill in the art will recognize thatthe invention can be embodied in other specific forms without departingfrom the spirit of the invention. For instance, this specificationrefers throughout to computational and network environments that includevirtual machines (VMs). However, virtual machines are merely one exampleof data compute nodes (DCNs) or data compute end nodes, also referred toas addressable nodes. DCNs may include non-virtualized physical hosts,virtual machines, containers that run on top of a host operating systemwithout the need for a hypervisor or separate operating system, andhypervisor kernel network interface modules.

VMs, in some embodiments, operate with their own guest operating systemson a host using resources of the host virtualized by virtualizationsoftware (e.g., a hypervisor, virtual machine monitor, etc.). The tenant(i.e., the owner of the VM) can choose which applications to operate ontop of the guest operating system. Some containers, on the other hand,are constructs that run on top of a host operating system without theneed for a hypervisor or separate guest operating system. In someembodiments, the host operating system uses name spaces to isolate thecontainers from each other and therefore provides operating-system levelsegregation of the different groups of applications that operate withindifferent containers. This segregation is akin to the VM segregationthat is offered in hypervisor-virtualized environments that virtualizesystem hardware, and thus can be viewed as a form of virtualization thatisolates different groups of applications that operate in differentcontainers. Such containers are more lightweight than VMs.

Hypervisor kernel network interface module, in some embodiments, is anon-VM DCN that includes a network stack with a hypervisor kernelnetwork interface and receive/transmit threads. One example of ahypervisor kernel network interface module is the vmknic module that ispart of the ESXi™ hypervisor of VMware, Inc. One of ordinary skill inthe art will recognize that while the specification refers to VMs, theexamples given could be any type of DCNs, including physical hosts, VMs,non-VM containers, and hypervisor kernel network interface modules. Infact, the example networks could include combinations of different typesof DCNs in some embodiments.

A number of the figures (e.g., FIGS. 5-9) conceptually illustrateprocesses. The specific operations of these processes may not beperformed in the exact order shown and described. The specificoperations may not be performed in one continuous series of operations,and different specific operations may be performed in differentembodiments. Furthermore, the process could be implemented using severalsub-processes, or as part of a larger macro process. In view of theforegoing, one of ordinary skill in the art would understand that theinvention is not to be limited by the foregoing illustrative details,but rather is to be defined by the appended claims.

The invention claimed is:
 1. A non-transitory machine readable mediumstoring a program for configuring a managed hardware forwarding element(MHFE) to implement a logical switch along with a plurality of othermanaged forwarding elements operating outside of the MHFE, and tocommunicatively couple the logical switch with a private network, theMHFE comprising a database with a logical switch table, a unicast mediaaccess control (MAC) table, and a physical switch table, the programcomprising sets of instructions for: providing a plurality of datatuples for defining the logical switch on the MHFE, without providing adata tuple for binding the logical switch to a port of the MHFE, whereinsaid plurality of data tuples are stored in the logical switch table andthe unicast MAC table; and after providing the plurality of data tuplesfor defining the logical switch, providing the data tuple that binds thelogical switch to a port of the MHFE, wherein said data tuple is storedin the physical switch table.
 2. The non-transitory machine readablemedium of claim 1, wherein the program provides the data tuples to theMHFE according to an order in which the data tuple for binding thelogical switch to the MHFE port is last.
 3. The non-transitory machinereadable medium of claim 1, wherein the MHFE comprises (i) a module thatretrieves the provided data tuples and uses the provided data tuples toconfigure dataplane forwarding records of the MHFE to implement thelogical switch and (ii) a forwarding engine that uses the forwardingrecords to process data messages that the MHFE receives, wherein themodule does not configure the dataplane forwarding records based on theprovided data tuples until the data tuple for binding the logical switchto the MHFE port is provided.
 4. The non-transitory machine readablemedium of claim 1, wherein the database uses a hardware VTEP (VXLANTunnel End Point) schema and the data tuples are provided to thedatabase on the MHFE by using a OVSdb (open vswitch database) protocol.5. The non-transitory machine readable medium of claim 1, wherein theprogram further comprises a set of instructions for ensuring that theplurality of data tuples are received by the MHFE before providing thedata tuple for binding the logical switch to the WIFE port.
 6. Thenon-transitory machine readable medium of claim 1, wherein the MHFE portis associated with multiple VLANs (virtual local area networks) and thebinding data tuple binds the logical switch to a VLAN associated withthe WIFE port.
 7. The non-transitory machine readable medium of claim 1,wherein the other forwarding elements that implement the logical switchalong with the MHFE comprise a plurality of software forwarding elementsthat execute on host computers on which data compute nodes execute.
 8. Amethod for configuring a managed hardware forwarding element (MHFE) toimplement a logical switch along with a plurality of other managedforwarding elements operating outside of the MHFE, and tocommunicatively couple the logical switch with a private network, theMHFE comprising a database with a logical switch table, a unicast mediaaccess control (MAC) table, and a physical switch table the methodcomprising: providing a plurality of data tuples for defining thelogical switch on the MHFE, without providing a data tuple for bindingthe LFE to a port of the MHFE, wherein said plurality of data tuples arestored in the logical switch table and the unicast MAC table; and afterproviding the plurality of data tuples for defining the logical switch,providing the data tuple that binds the logical switch to a port of theMHFE, wherein said data tuple is stored in the physical switch table. 9.The method of claim 8, wherein the data tuples are provided to the MHFEaccording to an order in which the data tuple for binding the logicalswitch to the MHFE port is last.
 10. The method of claim 8, wherein theMHFE comprises (i) a module that retrieves the provided data tuples anduses the provided data tuples to configure dataplane forwarding recordsof the MHFE to implement the logical switch and (ii) a forwarding enginethat uses the forwarding records to process data messages that the MHFEreceives, wherein the module does not configure the dataplane forwardingrecords based on the provided data tuples until the data tuple forbinding the logical switch to the MHFE port is provided.
 11. The methodof claim 8, wherein the database uses a hardware VTEP (VXLAN Tunnel EndPoint) schema and the data tuples are provided to the database on theMHFE by using a OVSdb (open vswitch database) protocol.
 12. The methodof claim 8 further comprising ensuring that the plurality of data tuplesare received by the MHFE before providing the data tuple for binding thelogical switch to the MHFE port.
 13. The method of claim 8, wherein theMHFE port is associated with multiple VLANs (virtual local areanetworks) and the binding data tuple binds the logical switch to a VLANassociated with the MHFE port.
 14. The method of claim 8, wherein theother forwarding elements that implement the logical switch with theMHFE comprise a plurality of software forwarding elements that executeon host computers on which data compute nodes execute.